The cytochrome chain of mitochondria exhibits variable H+/e- stoichiometry.

A study is presented of the ----H+/e- stoichiometry for H+ pumping by the cytochrome chain in isolated rat liver mitochondria under level-flow and steady-state conditions. It is shown that the ----H+/e- stoichiometry for the cytochrome chain varies under the influence of the flow rate and transmembrane delta microH+. The rate-dependence is shown to be associated with cytochrome c oxidase, whose ----H+/e- ratio varies from 0 to 1, whilst the ----H+/e- ratio for the span covered by cytochrome c reductase is invariably 2.     

The K+/site and H+/site stoichiometry of mitochondrial electron transport.

Electrode measurements of the average number of H+ ejected and K+ taken up (in the presence of valinomycin) per pair of electrons passing the energy-conserving sites of the respiratory chain of rat liver and rat heart mitochondria have given identical values of the H+/site and 5+/site ratios very close to 4 in the presence of N-ethylmaleimide, an inhibitor of interfering respiration-coupled uptake of H+ + H2PO4-. The K+/site uptake ratio of 4 not only shows that inward movement of K+ provides quantitative charge-compensation for the 4 H+ ejected, but also confirms that 4 charges are separated per pair of electrons per site. When N-ethylmaleimide is omitted, the H+/site ejection ratio is depressed, because of the interfering secondary uptake of H/+ with H2PO4- on the phosphate carrier, but the K+/site uptake ratio remains at 4.0. Addition of phosphate or acetate, which can carry H+ into respiring mitochondria, further depresses the H+/site ratio, but does not affect the K+/site ratio, which remains at 4.0. These and other considerations thus confirm our earlier stoichiometric measurements that the average H+/site ratio is 4.0 and also show that the K+/site uptake ratio can be used as a measure of the intrinsic H+/site ratio, regardless of the presence of phosphate in the medium and without the necessity of adding N-ethylmaleimide or other inhibitors of H+ + H2PO4- transport.     

Action of DCCD on the H+/O stoichiometry of mitoplast cytochrome c oxidase

The mechanistic H+/O ejection stoichiometry of the cytochrome c oxidase reaction in rat liver mitoplasts is close to 4 at level flow when the reduced oxidase is pulsed with O2. Dicyclohexylcarbodiimide (DCCD) up to 30 nmol/mg protein fails to influence the rate of electron flow through the mitoplast oxidase, but inhibits H+ ejection. The inhibition of H+ ejection appears to be biphasic; ejection of 2-3 H+ per O is completely inhibited by very low DCCD, whereas inhibition of the remaining H+ ejection requires very much higher concentrations of DCCD. This effect suggests the occurrence of two types of H+ pumps in the native cytochrome oxidase of mitoplasts.     

Theoretical analysis of H+/O stoichiometry during aerobic oxidation in E. coli in the stationary state

A general scheme of E. coli respiratory chain under aerobic oxidation with NAD.H2 is considered. The ratio H+/O is calculated by the currents method for the respiratory chain in a stationary state. The maximal possible stoichiometry is shown to equal 8. The origin of different H+/O values in the respiratory chains is discussed.     

The rapid alteration by tri-iodo-L-thyronine in vivo of both the ADP/O ratio and the apparent H+/O ratio in hypothyroid-rat liver mitochondria.

Mitochondria from the livers of thyroidectomized rats have a lowered ADP/O ratio, which can be restored to normal within 15 min after intravenous injection of a near-physiological dose of tri-iodothyronine. Thyroidectomy lowered the measured delta pH, which appears to be compensated by a rise (not statistically significant) in the membrane potential, so that the protonmotive force is unaltered. A simple simulation technique is described for use in estimating H+/O ratios by the oxygen-pulse technique, which circumvents the problem that this ratio can be seriously underestimated because of re-uptake of protons from the bulk phase by the mitochondria before their expulsion is complete. By this procedure the H+/O ratio of hypothyroid mitochondria is shown to be lowered by the same factor as the ADP/O ratio, and both these ratios are very rapidly restored in parallel by hormone administration. Although these findings could be consistent with a proposal that tri-iodothyronine rapidly modulates by some mechanism the efficiency of the respiratory-chain-linked proton pumps, the kinetic properties of the proton exchange suggest that the bulk-phase protons measured may not reflect faithfully those that drive the ATP synthetase.     

K+/H+ antiport in mitochondria

Mitochondria contain a latent K⁺/H⁺ antiporter that is activated by Mg²⁺-depletion and shows optimal activity in alkaline, hypotonic suspending media. This K⁺/H⁺ antiport activity appears responsible for a respiration-dependent extrusion of endogenous K⁺, for passive swelling in K⁺ acetate and other media, for a passive exchange of matrix⁴²K⁺ against external K⁺, Na⁺, or Li⁺, and for the respiration-dependent ion extrusion and osmotic contraction of mitochondria swollen passively in K⁺ nitrate. K⁺/H⁺ antiport is inhibited by quinine and by dicyclohexylcarbodiimide when this reagent is reacted with Mg²⁺-depleted mitochondria. There is good suggestive evidence that the K⁺/H⁺ antiport may serve as the endogenous K⁺-extruding device of the mitochondrion. There is also considerable experimental support for the concept that the K⁺/H⁺ antiport is regulated to prevent futile influx-efflux cycling of K⁺. However, it is not yet clear whether such regulation depends on matrix free Mg²⁺, on membrane conformational changes, or other as yet unknown factors.     

Purification of a reconstitutively active K+/H+ antiporter from rat liver mitochondria

We describe purification of three different states of the 82-kDa K+/H+ antiporter from rat liver mitochondria. The denatured 82-kDa protein, identified by its selective labeling with [14C]dicyclohexylcarbodiimide (DCCD), was purified by preparative two-dimensional gel electrophoresis. This purified product was used to raise and immunopurify monospecific polyclonal antibodies. Western blot analysis showed that the [14C] DCCD-labeled 82-kDa protein is not a DCCD-crosslinked product. The native, [14C]DCCD-labeled, 82-kDa protein was purified by (NH4)2SO4 fractionation and column chromatography, using 14C labeling and gel electrophoresis to track the protein. The native, non-DCCD-labeled 82-kDa protein was purified by similar procedures, using immunopurified antibodies to track the protein. DCCD binding had no effect on chromatographic behavior of the antiporter protein. This protocol resulted in purification of the 82-kDa protein to apparent homogeneity. The purified, native 82-kDa protein was reconstituted into proteoliposomes and assayed for K+ transport with the new fluorescent probe, PBFI. K+ transport was electroneutral and was inhibited by DCCD, Mg2+, and timolol. The turnover number for K+ transport was about 1000 s-1, very similar to the value previously estimated in intact mitochondria.     

A theoretical analysis of the effect of phosphate on apparent H+/O stoichiometries in oxygen-pulse experiments with rat liver mitochondria

It is now generally accepted that, in oxygen-pulse experiments on rat-liver mitochondria suspended in KCl-based media, the rapid import of H+ with phosphate leads to an approx. 33% lowering of apparent H+/O stoichiometry. However, in low-K+ media, N-ethylmaleimide has no effect on stoichiometry, and there appears to be no import of H+ with phosphate. In this paper the quantitative effect of extramitochondrial phosphate on apparent H+/O stoichiometry is calculated theoretically, on the basis of internal and external buffering powers. The lack of appreciable phosphate uptake in low-K+ media is quantitatively explained in terms of several factors, including the initial pH gradient and initial phosphate distribution.     

Noradrenaline treatment of rats stimulates H2O2 generation in liver mitochondria.

Treatment of rats with noradrenaline stimulated H2O2 generation in liver mitochondria using succinate, choline or glycerol 1-phosphate as substrate. The dehydrogenase activity with either succinate or choline as substrate showed no change, whereas that with glycerol 1-phosphate increased. The effect was obtained with noradrenaline, but not with dihydroxyphenylserine. Phenoxybenzamine and yohimbine, but not propranolol, prevented the response to noradrenaline treatment. Phenylephrine could stimulate H2O2 generation, whereas isoprenaline had only a marginal effect. Theophylline treatment slightly decreased the generation of H2O2 in liver mitochondria, but treatment with pargyline, Ro4-1284 and dibutyryl cyclic AMP had little effect. These studies showed that noradrenaline might possibly be acting through the alpha 2-adrenergic system.     

K+/H+ antiport in heart mitochondria

Heart mitochondria depleted of endogenous divalent cations by treatment with A23187 and EDTA swell in (a) K+ acetate or (b) K+ nitrate when an uncoupler is present. These mitochondria also exchange matrix 42K+ with external K+, Na+, or Li+ in a reaction that does not require respiration and is insensitive to uncouplers. Untreated control mitochondria do not swell in either medium nor do they show the passive cation exchange. Both the swelling and the exchange reactions are inhibited by Mg2+ and by quinine and other lipophilic amines. Swelling and exchange are both strongly activated at alkaline pH, and the exchange reaction is also increased markedly by hypotonic conditions. All of these properties correspond to those reported for a respiration-dependent extrusion of K+ from Mg2+-depleted mitochondria, a reaction attributed to a latent Mg2+- and H+-sensitive K+/H+ antiport. The swelling reactions are strongly inhibited by dicyclohexylcarbodiimide reacted under hypotonic conditions, but the exchange reaction is not sensitive to this reagent. Heart mitochondria depleted of Mg2+ show marked increases in their permeability to H+, to anions, and possibly to cations, and the permeability to each of these components is further increased at alkaline pH. This generalized increase in membrane permeability makes it likely that K+/H+ antiport is not the only pathway available for K+ movement in these mitochondria. It is concluded that the swelling, 42K+ exchange, and K+ extrusion data are all consistent with the presence of the putative K+/H+ antiport but that definitive evidence for the participation of such a component in these reactions is still lacking.     

H+/ATP stoichiometry of proton pump of turtle urinary bladder

Urinary acidification in the turtle urinary bladder is due to a reversible proton-translocating ATPase. To estimate the H+/ATP stoichiometry of this pump, we measured the delta G'ATP in the epithelial cells and the maximum e.m.f. generated by the pump. The latter is the maximal transepithelial electrochemical gradient for protons placed across the epithelium that is needed to nullify the rate of transport and averaged 179 +/- 7 mV. The delta G'ATP averaged 50.1 kJ/mol. The H+/ATP stoichiometry of these bladders was 2.92 +/- 0.1. In other experiments, the bladders were poisoned by iodoacetate and cyanide and a variable transepithelial electrochemical gradient for protons was placed across them. It was noted that ATP synthesis occurred at a transepithelial electrochemical gradient for protons greater than 120 mV. The delta G'ATP in other bladders treated identically averaged 40.0 kJ/mol, giving a H+/ATP stoichiometry of 3.4 +/- 0.1. We conclude that the H+/ATP stoichiometry of the proton pump of turtle urinary bladder is approximately 3.     

H+/ATP stoichiometry for the gastric (K++H+)-ATPase

Summary The initial rate of ATP-dependent proton uptake by hog gastric vesicles was measured at pH's between 6.1 and 6.9 by measuring the loss of protons from the external space with a glass electrode. The apparent rates of proton loss were corrected for scalar proton production due to ATP hydrolysis. For vesicles in 150mm KCl and pH 6.1, corrected rates of proton uptake and ATP hydrolysis were 639±84 and 619±65 nmol/min×mg protein, respectively, giving an H⁺/ATP ratio of 1.03±0.7. Furthermore, at all pH's tested the ratio of the rate of proton uptake to the rate of ATP hydrolysis was not significantly different than 1.0. No proton uptake (<10 nmol/min×mg protein) was exhibited by vesicles in 150mm NaCl at pH 6.1 despite ATP hydrolysis of 187±46 nmol/min×mg (nonproductive hydrolysis). Comparison of the rates of proton transport and ATP hydrolysis in various mixture of KCl and NaCl showed that the H⁺/ATP stoichiometries were not significantly different than 1.0 at all concentrations of K⁺ greater than 10mm. This fact suggests that the nonproductive rate is vanishingly small at these concentrations, implying that the measured H⁺/ATP stoichiometry is equal to the enzymatic stoichiometry. This result shows that the isolated gastric (K⁺+H⁺)-ATPase is thermodynamically capable of forming the observed proton gradient of the stomach.     

The gastric [H,K]ATPase:H+/ATP stoichiometry

An H+/ATP ratio of 2 for H+ transport was determined from initial rate measurements at pH 6.1 in a purified gastric microsomal fraction containing the [H,K]ATPase. This ratio was independent of external KCl, though the apparent K0.5 for ATP was increased from 10.78 +/- 0.51 (n = 3) to 64.6 +/- 11.9 (n = 3) microM ATP and from 5.13 +/- 0.64 (n = 3) to 65.2 +/- 0.64 (n = 3) microM ATP for H+ transport and the K+-stimulated ATPase, respectively, as K+external was increased from 12 to 150 mM. The H+/ATP ratio was also relatively independent of ATP concentration. Maximum initial rates obtained in KCl-equilibrated vesicles were independent of added valinomycin, though net H+ transport was increased 29.3 +/- 1.03% (n = 6) by the addition of ionophore. Maximum net H+ transport in this vesicle preparation was 185 +/- 2.1 (n = 14) nmol mg-1 of protein. Initial rate measurements of ATPase represent a burst of K+-dependent activity of approximately 10-15 s duration. The H+/ATP stoichiometry was calculated based on the K+-stimulated component of hydrolysis. Under most conditions, the Mg2+-dependent component of hydrolysis was less than 10% of the (Mg2+ + K+) component of hydrolysis.     

The H+/O ratio of proton translocation linked to the oxidation of succinate by mitochondria

In a recent communication Lehninger and co-workers (Costa, L.E., Reynaferje, B., and Lehninger, A.L. (1984) J. Biol. Chem. 259, 4802-4811) reported values approaching 8 for the H+/O ratio of vectorial proton ejection from rat liver mitochondria respiring with succinate. Here we present a rigorous analysis of these measurements which reveals that they may significantly overestimate the true H+/O stoicheiometry.     

Proton pathways and H+/Cl- stoichiometry in bacterial chloride transporters

H+/Cl- antiport behavior has recently been observed in bacterial chloride channel homologs and eukaryotic CLC-family proteins. The detailed molecular-level mechanism driving the stoichiometric exchange is unknown. In the bacterial structure, experiments and modeling studies have identified two acidic residues, E148 and E203, as key sites along the proton pathway. The E148 residue is a major component of the fast gate, and it occupies a site crucial for both H+ and Cl- transport. E203 is located on the intracellular side of the protein; it is vital for H+, but not Cl-, transport. This suggests two independent ion transit pathways for H+ and Cl- on the intracellular side of the transporter. Previously, we utilized a new pore-searching algorithm, TransPath, to predict Cl- and H+ ion pathways in the bacterial ClC channel homolog, focusing on proton access from the extracellular solution. Here we employ the TransPath method and molecular dynamics simulations to explore H+ pathways linking E148 and E203 in the presence of Cl- ions located at the experimentally observed binding sites in the pore. A conclusion is that Cl- ions are required at both the intracellular (S(int)) and central (S(cen)) binding sites in order to create an electrostatically favorable H+ pathway linking E148 and E203; this electrostatic coupling is likely related to the observed 1H+/2Cl- stoichiometry of the antiporter. In addition, we suggest that a tyrosine residue side chain (Y445), located near the Cl- ion binding site at S(cen), is involved in proton transport between E148 and E203.     

Altered stoichiometry of the human leucocyte Na+/H+ antiport with decreasing pH.

The Na+/H+ antiport is an important regulator of cellular volume, pH and Na+ concentration in mammalian cells. The stoichiometry of this antiporter has previously been shown to be a 1:1 exchange of internal H+ for external Na+. We have investigated this stoichiometry in human leucocytes by using a novel intracellular pH-clamping technique and measuring 22Na+ influx and H+ efflux in the same cells. As internal pH was lowered, the stoichiometry of H+/Na+ exchange rose to a mean +/- S.D. of 2.23 +/- 0.69. This mechanism allows a higher H+ efflux in the face of intracellular acid stress without causing excessive intracellular Na+ overload.     

H+/e- stoichiometry of mitochondrial cytochrome complexes reconstituted in liposomes. Rate-dependent changes of the stoichiometry in the cytochrome c oxidase vesicles.

The H+/e- stoichiometry of protonmotive cytochrome c oxidase, isolated from bovine heart mitochondria and reconstituted in liposomes, has been determined by making use of direct spectrophotometric measurements of the initial rates of e- flow and H+ translocation. It is shown that the ----H+/e- ratio for redox-linked proton ejection by the oxidase varies from around 0 to a maximum of 1 as a function of the rate of overall electron flow in the complex.     

The H+/O ratio of proton translocation linked to the oxidation of succinate by mitochondria. Reply to a commentary

Costa, L.E., Reynafarje, B. and Lehninger, A.L. [(1984) J. Biol. Chem. 259, 4802-4811] have reported 'second-generation' measurements of the H+/O ratio approaching 8.0 for vectorial H+ translocation coupled to succinate oxidation by rat liver mitochondria. In a Commentary in this Journal [Krab, K., Soos, J. and Wikstr?m, M. (1984) FEBS Lett. 178, 187-192] it was concluded that the measurements of Costa et al. significantly overestimated the true H+/O stoichiometry. It is shown here that the mathematical simulation on which Krab et al. based this claim is faulty and that data reported by Costa et al. had already excluded the criticism advanced by Krab et al. Also reported are new data, obtained under conditions in which the arguments of Krab et al. are irrelevant, which confirm that the H+/O ratio for succinate oxidation extrapolated to level flow is close to 8.